胸腺内注射异基因抗原诱导鼠神经移植免疫耐受的实验研究

目的探讨小鼠胸腺内注射异基因抗原在同种异体异基因坐骨神经移植免疫耐受中的作用。方法自供体小鼠C57BL／6的脾细胞中提取MHC抗原注人受体鼠Balb／c小鼠胸腺内，于2周后移植供体鼠坐骨神经。48只Balb／c小鼠随机分为4组，A组（胸腺内注射组）、B组（自体神经移植组）、C组（冷冻异体神经移植组）、D组（异体神经移植加用免疫抑制剂组）。于3周后进行电生理学、组织学、免疫学检测。结果A组运动神经传导速度（38．23m／s）与D组（36．39m／s）相比无显著性差异（P〉0．05），组织学、电镜、免疫学（混合淋巴细胞培养及迟发性超敏反应）检测结果均证实B组分别优于A组、D组和C组。结论胸腺内注射异基因MHC抗原可诱导大鼠对异体坐骨神经移植的特异性免疫耐受。     

国人胎儿胸腺的生长发育

称量了14—38周共56例引产胎儿胸腺的重量并观察了6—38周共25例引产胎儿胸腺的组织结构,认为胸腺在胚胎时期生长速度较快。光镜观察,6周已出现胸腺的始基,第9周开始出现淋巴细胞,12周开始分叶,13周以后,皮质髓质渐趋分明并出现胸腺小体,15周后胸腺小叶增多变宽,新小叶形成旺盛,胸腺小体增多,至28周后结构已近似成熟。     

萎缩胸腺内网状上皮细胞的形态学观察

104例尸检萎缩胸腺组织,用PAP法进行抗角蛋白多克隆抗体检测及组织学观察,发现61例病理性重度萎缩胸腺中,网状上皮细胞有4种分布类型①正常分布,②小叶中心集中分布,③小叶内平均分布,④消减型.7例生理性萎缩胸腺,均为消减型.胸腺网状上皮细胞形态有具细长突起(皮质)及短突起(髓质)2型.萎缩胸腺内有60.7%呈网状上皮增生,尤以髓质区明显.有12例胸腺组织行扫描电镜观察,见胸腺重度萎缩呈疏网型、蜂巢型及消减型序列发生.     

Induction of apoptotic cell death in rat thymus and spleen after a bolus injection of methamphetamine

We examined whether methamphetamine (MAP) induced apoptotic cell death in vivo. Male Wistar rats were injected intraperitoneally with 25 mg MAP/Kg body weight and were sacrificed at 4, 8 and 24 h. As early as 4 h after a single dose of MAP, DNA ladder bands representing DNA fragmentation into multiples of the internucleosomal DNA length of about 180 by were observed by gel electrophoresis in thymic and splenic DNA. DNA from control rats injected with 1 ml physiological saline/Kg body weight showed no ladder band patterns. The proportion of fragmented DNA from the thymus increased in a time-dependent manner up to 8 h and faint ladder band patterns were observed at 24 h, indicating that cell death via apoptosis occurred at an early stage and then apoptotic bodies were scavenged. DNA fragmentation in the thymus and spleen induced with MAP was also confirmed by the terminal deoxynucleotidyl transferase-mediated dUTPbiotin nick end labeling (TUNEL) method in situ. In control thymus samples, stained cells were numerous in the cortex but sparse in the medulla. At the boundary area between the cortex and medulla, stained cells were seen as a layer. In the MAP-treated rats, stained cells were increased and dispersed equally in the cortex and medulla. In control spleen samples, stained cells were numerous in all areas excluding the germinal centers. Cells at the germinal centers were stained intensively in MAP-treated rat spleen. Light microscopical analyses allowed us to identify lymphocytes during the course of apoptotic cell death. Electron microscopic studies showed morphological landmarks for the process of cellular apoptosis in both organs e.g. lymphocytes with chromatin condensed into crescents at the periphery of the nuclei and apoptotic bodies. These results indicate that MAP induced cell death of the thymic and splenic lymphocytes via apoptosis.     

重症肌无力患者胸腺肥大细胞的形态数量和超微结构研究

为探讨研究重症肌无力（ＭＧ）患者胸腺内肥大细胞的形态数量和其超微结构变化与ＭＧ发病的关系。方法对２８例ＭＧ患者作胸腺肥大细胞的形态半定量分析和光镜观察，其中１６例的胸腺进行电镜检查。结果ＭＧ胸腺不仅表现组织学异常，且肥大细胞数量明显增多，尤其是在非增生胸腺内出现大量肥大细胞，而在增生的髓质和生发中心区几乎见不到。电镜观察提示肥大细胞与上皮细胞、Ｔ淋巴细胞和毛细血管关系密切，且含多种形态的分泌颗粒。结论肥大细胞对胸腺细胞的分化成熟、胸腺屏障和胸腺功能，以及ＭＧ发病均起到一定的重要作用。     

The afferent innervation of the thymus gland in the rat

The afferent nervous supply to the thymus gland has been investigated by means of the retrograde transport of horseradish peroxidase. It has been shown that the thymus receives an afferent supply from the nodose ganglia of the vagus and from the dorsal root ganglia C₁–C₇. The afferent innervation of the right and left thymic lobes is bilaterally organized; the fibers of a small celled population of nodose ganglion neurons cross outside the thymus and those of a larger celled population cross within the thymus gland. The functional implications of these findings are discussed in the context of central nervous system-immune system interactions.     

Myelopoiesis in the thymus of the sea bass,Dicentrarchus labrax L. (teleost)

Background: In vertebrates the thymus is primarily regarded as a lymphoid organ whose importance lies in its capacity to produce a large number of lymphocytes that enter the circulation as T cells. In higher vertebrates the organ has also been regarded as a site for my elopoiesis, but this capacity has not been observed in fish. In this study we describe morphologically the presence of intrathymic developing myeloid cells in the sea bass. Methods: The thymus samples were morphologically studied by transmission electron microscopy. Results: We describe the coexistence of cells in different stages of erythropoiesis and granulopoiesis that appear to be developing in situ in some thymus lobes. Degenerated thymocytes and epithelial-reticular cells occur simultaneously in the same areas. Conclusions: The coexistence of different cellular components of erythropoiesis and the heterophilic series of granulopoiesis with areas of necrosis suggests a relationship between both processes that is influenced by the microenvironment. Our observations also suggest that the presence of intrathymic developing myeloid cells may imply a nonimmunological role for the thymus. © 1995 Wiley-Liss, Inc.     

Split tolerance in chimeric GVH mice

Abstract The i.v. inoculation of parental spleen cells into unirradiated adult F1 hybrid mice results in a graft-versus-host reaction (GVHR). In the strain combination B10D2±(B10.BRx B10.D2) F1, this reaction is associated with thymic injury and transient but profound cellular immune deficiency. We further analysed the immune status of these mice 60 days after GVHR induction. Phenotypic studies of spleen cells showed that these mice were re-populated with parental lymphocytes resulting in a high degree of chimerism (85%). At this time, the mice looked healthy and recovered a normal cytotoxic T cell response (CTL) against allogeneic cells. GVH chimeric splenocytes were unresponsive against F 1 hybrid cells in mixed lymphocyte culture (MLC), but exhibited anti-F1 CTL reactivity. We also analysed the anti-F 1 reactivity of these mice in vivo. GVH chimeric splenocytes were unable to induce GVHR after injection into a new F1 hybrid and F1 GVH mice specifically rejected F1 bone marrow (BM) cells after lethal irradiation. Grafting a neonatal parental thymus prevented the rejection of F1 BM cells and restored CTL alloreactivity. It is concluded that the chimeric state induced by GVHR is associated with a split tolerance and that a radiosensitive thymic-dependent mechanism is involved in maintaining self-tolerance in these mice.     

Thymus in myasthenia gravis: a light and electron microscopic study of a case with thymic follicular hyperplasia

The present study has focused mainly on microenvironmental aspects of the thymus from a 17-year-old female patient suffering from myasthenia gravis. The most striking lightmicroscopic feature was again the well known presence of lymphoid follicular hyperplasia. Ultrastructurally, the configuration, cellular composition and fine structure were to a large extent the same as in other, peripheral lymphoid organs. Cells showing the typical morphologic characteristics of fibroblastic reticulum cells, which are most probably precursors of dendritic reticulum cells, were observed within germinal centers. Additionally the morphology of the unaffected medulla and corticomedullary region was studied, thereby paying particular attention to the structural changes of interdigitating cells. These contained frequently Birbeck granules, which have not been described before in human thymus.     

Thymic stromal cell specialization and the T-cell receptor repertoire

Ten years ago, we proposed a model for thymus function in which thymic epithelial cells are primarily responsible for imprinting major histocompatibility complex (MHC)-restricted specificity, and bone marrow-derived macrophages or dendritic cells are responsible for the induction of self-tolerance. Since then, transgenic and knockout models have allowed for a dissection of thymic stromal components in vivo, leading to a new understanding of their specialized functions. We have determined that with regard to class II-restricted CD4 T-cell development, two distinct subsets of thymic epithelium help shape the repertoire: Cortical epithelium appears solely responsible for positive selection, whereas a fucose-bearing subset of medullary epithelium is specialized for negative selection. This absolute separation of positive and negative selection into two distinct spatial and temporal compartments leads to a much simpler view of the process of repertoire selection. Finally, a novel view of the function of the thymic medulla is discussed.